Method and apparatus for transmitting wideband speech signals

ABSTRACT

A method and an apparatus for transmitting a speech signal are provided. A speech signal transmitter includes a quadrature mirror filter, a base sub-band encoder, an enhancement sub-band encoder, and a network connector. The quadrature mirror filter receives a speech signal, divides the speech signal into an enhancement band speech signal and a base band speech signal, and outputs the enhancement band speech signal and the base band speech signal. The base sub-band encoder receives and encodes the base band speech signal. The enhancement sub-band encoder receives and encodes the enhancement band speech signal. The network connector multiplexes the encoded enhancement band speech signal and the encoded base band speech signal based on the kinds of networks over which speech signals are transmitted, and transmits the multiplexed signals to the networks. A speech signal is multiplexed and transmitted by various methods based on the kinds of networks. Thus, the speech signal can be efficiently transmitted.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a U.S. continuation of U.S. patent application Ser.No. 12/292,021, now pending, filed Nov. 10, 2008, which is acontinuation of U.S. patent application Ser. No. 11/748,369 (now U.S.Pat. No. 7,467,082), filed May 14, 2007, which is a continuation of U.S.patent application Ser. No. 10/222,662 (now U.S. Pat. No. 7,233,893),filed Aug. 16, 2002,which claims the priority of Korean PatentApplication No. 2001-81121, filed Dec. 19, 2001 in the KoreanIntellectual Property Office, the disclosures of which are incorporatedherein by reference.

BACKGROUND

1. Field

The present invention relates to a method and an apparatus fortransmitting speech signals, and more particularly, to a method and anapparatus for wideband encoding of speech signals and transmission ofthe encoded bit stream.

2. Description of the Related Art

Conventionally, various coding methods have been proposed to digitizeand process speech signals. General speech signal processing methods areclassified into two types: in one, 16 bit linear pulse code modulationdata is obtained by sampling input analog speech signals at 8 kHz andinput to an encoder; in the other, 16 bit linear pulse code modulationdata is obtained by sampling input analog speech signals at 16 kHz andinput to an encoder. In the former method, speech signals are coded bymethods including G.711-G.712 pulse code modulation (PCM) andG.720-G.729 non-PCM standards of the International TelecommunicationUnion—Telecommunication Standardization Sector (ITU-T). In the lattermethod, speech signals are coded by G.722 and G.722.1 of the ITU-T andan adaptive multi-rate wideband (AMR-WB) method, which will be used inIMT-2000.

Here, G.723.1, which is a standard for compressing multimedia signals ata lower rate, is an algorithm for compressing and restoring input speechat a dual rate of 5.3/6.3 kbit/s and provides toll quality on a cablenetwork. G.723.1 uses a Hybrid coding technique combining a waveformcoding method and a parametric coding method, and is a Code ExcitedLinear Prediction (CELP)-based speech coder. G. 729, which is a standardfor IMT-2000 to expand the frequency efficiency for mobilecommunications, is an algorithm for compressing and restoring inputspeech at a rate of 8 kbit/s. G.729A is reduced complexity version ofthe G.729 coder. This version is bitstream interoperable with the fullversion.

G.729A also provides toll quality on a cable network and uses a Hybridcoding technique and a CELP-based speech coder. ITU-T G.722, which is astandard for coding wideband audio signals, has a transmission rate of64, 56, or 48 kbit/s and face-to-face communication quality. Also, G.722divides one band into two sub-bands and codes each of the two sub-bands,using an Adaptive Differential Pulse Code Modulation (AD-PCM) method.

Methods and apparatuses for providing toll quality on a cable networkand coding speech at a lower rate have enabled new services in mobilecommunications and telephony due to high frequency efficiency. Inparticular, the services using Voice over Internet Protocol (VoIP) overInternet networks are rapidly becoming widespread because of their lowtelephone rates. However, conventional coding methods and apparatuseshave the problem of low service quality due to low toll quality and longdelay over Internet networks. Thus, the conventional coding methods andapparatuses do not have a good reputation.

Accordingly, in order to solve these problems, various attempts havebeen made. For example, if speech signals are sampled at a frequency of16 kHz in a VoIP system before coding, the quality of the speech signalsmay be much improved. However, current 16 kHz wideband speech codecs arenot at all compatible with the codec currently used in the VoIP service.Thus, a new system is needed. Also, since wideband signals have a widefrequency bandwidth, networks with a large data processing capacity areneeded. Thus, starting new services in disregard of current systems hasmany difficulties.

SUMMARY

To solve the above-described problems, it is a first object of thepresent invention to provide a speech signal transmitter which iscompatible with a conventional system and provides high quality widebandspeech signals.

It is a second object of the present invention to provide a speechsignal receiver which is compatible with a conventional system andprovides high quality wideband speech signals.

It is a third object of the present invention to provide a method oftransmitting speech signals which is compatible with a conventionalsystem and provides high quality wideband speech signals.

It is a fourth object of the present invention to provide a method ofreceiving speech signals which is compatible with a conventional systemand provides high quality wideband speech signals.

Accordingly, to achieve the first object, there is provided a speechsignal transmitter including a quadrature mirror filter, a base sub-bandencoder, an enhancement sub-band encoder, and a network connector. Thequadrature mirror filter receives a speech signal, divides the speechsignal into an enhancement band speech signal and a base band speechsignal, and outputs the enhancement band speech signal and the base bandspeech signal. The base sub-band encoder receives and encodes the baseband speech signal. The enhancement sub-band encoder receives andencodes the enhancement band speech signal. The network connectormultiplexes the encoded enhancement band speech signal and the encodedbase band speech signal based on the kinds of networks over which speechsignals are transmitted, and transmits the multiplexed signals to thenetworks. The base sub-band encoder encodes the base band speech signalbased on G.723.1 or G.729A. The network connector simultaneously packetsthe enhancement band speech signal and the base band speech signal orpackets only the base band speech signal, if the networks are composedonly of networks guaranteeing or of networks not guaranteeing quality ofservice, and packets and transmits the base band speech signal to thenetworks guaranteeing quality of service and packets and transmits theenhancement band speech signal to the networks not guaranteeing qualityof service, if the networks are composed of networks guaranteeingquality of service and networks not guaranteeing quality of service. Thespeech signal has a sampling frequency of 16 kHz and a bandwidth of 0-8kHz, the enhancement band speech signal has a sampling frequency of 8kHz and a bandwidth of 4 kHz-8 kHz, and the base band speech signal hasa sampling frequency of 8 kHz and a bandwidth of 0-4 kHz. The speechsignal transmitter further includes an acoustic echo canceller forreceiving the speech signal, canceling echoes from the speech signal,and outputting the speech signal to the quadrature mirror filter.

To achieve the second object, there is provided a speech signal receiverincluding a network connector, an enhancement sub-band decoder, a basesub-band decoder, and a quadrature mirror filter. The network connectorreceives a speech signal, within which an enhancement band speech signaland a base band speech signal are multiplexed based on the kinds ofnetworks through which speech signals are transmitted, demultiplexes themultiplexed speech signal, and extracts an enhancement band digitalspeech signal and a base band digital speech signal. The enhancementsub-band decoder receives and decodes the enhancement band speechsignal. The base sub-band decoder receives and decodes the base bandspeech signal. The quadrature mirror filter synthesizes the decodedenhancement band speech signal and the decoded base band speech signalinto a single speech signal. The base sub-band decoder decodes the baseband speech signal based on G.723.1 or G.729A. The enhancement bandspeech signal has a sampling frequency of 8 kHz and a bandwidth of 4-8kHz, and the base band speech signal has a sampling frequency of 8 kHzand a bandwidth of 0-4 kHz. The speech signal receiver further includesan acoustic echo canceller for canceling echoes from the synthesizedsingle speech signal.

To achieve the third object, there is provided a method of transmittinga speech signal. An analog speech signal is received and converted intoa digital speech signal. The digital speech signal is divided into anenhancement band speech signal and a base band speech signal. Theenhancement band speech signal and the base band speech signal areseparately encoded. The encoded enhancement band speech signal and theencoded base band speech signal are multiplexed based on the kinds ofnetworks to which the speech signal is transmitted, and the multiplexedenhancement band speech signal and the multiplexed base band speechsignal are transmitted to the networks. The step of receiving andconverting the analog speech signal includes canceling echoes from thedigital speech signal. In the step of multiplexing the encodedenhancement band speech signal and the encoded base band speech signaland transmitting the multiplexed enhancement band speech signal and themultiplexed base band speech signal to the networks, if the networks arecomposed only of networks guaranteeing or of networks not guaranteeingquality of service, then the enhancement band speech signal and the baseband speech signal are simultaneously packeted or only the base bandspeech signal is packeted, and if the networks are composed of networksguaranteeing quality of service and networks not guaranteeing quality ofservice, the base band speech signal is packeted and transmitted to thenetworks guaranteeing quality of service and the enhancement band speechsignal is packeted and transmitted to the networks not guaranteeingquality of service.

To achieve the fourth object, there is provided a method of receiving aspeech signal. A speech signal, within which an enhancement band speechsignal and a base band speech signal are multiplexed based on the kindsof networks through which speech signals are transmitted, is received.The multiplexed enhancement band speech signal and the multiplexed baseband speech signal are demultiplexed, and an enhancement band digitalspeech signal and a base band digital speech signal are extracted. Theenhancement band digital speech signal and the base band digital speechsignal are decoded. The decoded enhancement band digital speech signaland the decoded base band digital speech signal are synthesized into asingle speech signal. The step of synthesizing the decoded enhancementband digital speech signal and the decoded base band digital speechsignal into a single speech signal includes canceling echoes from thesynthesized one speech signal.

BRIEF DESCRIPTION OF THE DRAWINGS

The above objects and advantages of the present invention will becomemore apparent by describing in detail preferred embodiments thereof withreference to the attached drawings in which:

FIG. 1 is a diagram showing a preferred embodiment of the transmissionof wideband speech signals via a network according to the presentinvention;

FIG. 2 is a diagram of the structure of a preferred embodiment of aspeech signal coder according to the present invention;

FIG. 3 is a diagram of the structure of a preferred embodiment of aspeech signal transmitter according to the present invention;

FIG. 4 is a flowchart of a preferred embodiment of a method oftransmitting speech signals according to the present invention;

FIG. 5 is a diagram of the structure of a preferred embodiment of aspeech signal decoder according to the present invention;

FIG. 6 is a diagram of the structure of a preferred embodiment of aspeech signal receiver according to the present invention;

FIG. 7 is a flowchart of a preferred embodiment of a method of receivingspeech signals according to the present invention;

FIG. 8 is a diagram of the structure of a preferred embodiment of anaudio communication terminal according to the present invention; and

FIG. 9 is a diagram of the structure of a general Voice over InternetProtocol (VoIP) service.

DESCRIPTION OF EMBODIMENTS

Hereinafter, a preferred embodiment of the present invention will bedescribed in detail with reference to the attached drawings.

FIG. 1 is a diagram showing a preferred embodiment of the transmissionof a wideband speech signals via a network according to the presentinvention. Here, a network guaranteeing the quality of service (QoS) anda network not guaranteeing the QoS are simultaneously provided.

Internet Protocol (IP) terminals 101 and 106, which are terminals suchas microphones, speakers, and telephones for receiving and outputtingspeech signals, generate and transmit IP packets. The terminals may havevarious shapes such as telephone sets or personal computers (PC). When apacket generated in the IP terminal 101 is transmitted to the IPterminal 106, the packet is divided into a base band packet 105 and anenhancement band packet 102. The numbers in packets 102 and 105represent time stamps. The base band packet 105 has importantinformation on the speech communications and thus is transmitted via anetwork 104 guaranteeing QoS. If only the base band is used, a personcan at least communicate with another person, although theintelligibility and naturalness of their voice is considerablydecreased. Thus, if a user wants face-to-face sound quality, the userdecodes the enhancement band packet 102 transmitted over the network 103not guaranteeing the QoS, giving high sound quality. Since a packettransmitted over the network 103 not guaranteeing the QoS has irregulardelay, packet error, and jitter, the quality of sound is maximized usinga device for improving the QoS such as a jitter buffer and a frameerasure concealment (FEC) device in order to synchronize the packetsreceived by the receiving IP terminal 106.

FIG. 2 is a diagram of the structure of a preferred embodiment of aspeech signal coder according to the present invention. A quadraturemirror filter (QMF) 201 receives a digital speech signal, which is a 16bit linear pulse code modulation (PCM) signal having a bandwidth of 0-8kHz sampled at 16 kHz, and outputs a base band signal having a bandwidthof 0-4 kHz sampled at 8 kHz and an enhancement band signal having abandwidth of 4-8 kHz sampled at 8 kHz. An enhancement sub-band encoder202 receives and encodes the enhancement band signal using a waveformcoding method or a transform coding method, to output an enhancementspeech signal. A base sub-band encoder 203 receives and encodes the baseband signal according to G.723.1 or G.729A methods, to output a baseband speech signal.

FIG. 3 is a diagram of the structure of a preferred embodiment of aspeech signal transmitter according to the present invention. An NDconverter 301 receives a user's analog speech signal through amicrophone and converts the analog speech signal into a digital speechsignal.

An acoustic echo canceller 302 cancels echoes from the speech signalreceived from the A/D converter 301. The acoustic echo canceller 302 maybe an acoustic echo canceller according to ITU-T G.167. The signalsinput into and output from the acoustic echo canceller 302 are 16 bitlinear PCM signals sampled at 16 kHz, with a bandwidth of 0-8 kHz.

An encoder 303 receives the signal output from the acoustic echocanceller 302 and separately encodes a base band signal and anenhancement band signal. The detailed structure of the encoder 303 isshown in FIG. 2.

An IP Network Interface 304 multiplexes an input signal composed of abase band and an enhancement band in various ways, according to thestructure of the IP Network, to efficiently transmit packets. If all IPnetworks provided for speech signal communication guarantee the QoS,then the base band signal and the enhancement band signal aresimultaneously packeted or only the base band signal is packeted. If anetwork guaranteeing the QoS and a network not guaranteeing the QoS aresimultaneously provided, the relatively important base band signal istransmitted through the network guaranteeing the QoS, and theenhancement band signal is transmitted through the network notguaranteeing the QoS. Here, although packet errors and jitter occur inthe network not guaranteeing the QoS, sound quality is higher than whenonly the base band signal is used. If all the IP networks do notguarantee the QoS, then the base band signal and the enhancement bandsignal are simultaneously packeted or only the base band signal ispacketed.

The IP Network Interface 304 generates packets in the form shown in FIG.9. Currently VoIP is composed of the combination of various protocols,but the present invention may be applied to the combination of anyprotocols mentioned here.

FIG. 4 is a flowchart of a preferred embodiment of a method oftransmitting speech signals according to the present invention. Ananalog speech signal is received and is converted into a digital speechsignal in step 401. Echoes are cancelled from the digital speech signalin step 402. The digital speech signal is divided into an enhancementband signal and a base band signal in step 403. The enhancement bandsignal and the base band signal are separately encoded in step 404. Theencoded speech signal is multiplexed in various combinations accordingto the kinds of connected networks in step 405. The multiplexed signalis packeted and transmitted to the networks in step 406.

Here, the digital speech signal, into which the analog speech signal isconverted, is a 16 bit linear PCM signal sampled at 16 kHz. The baseband signal is sampled at 8 kHz and has a bandwidth of 0-4 kHz. Theenhancement band signal is sampled at 8 kHz and has a bandwidth of 4-8kHz. The base band signal may be coded by G.723.1 or G.729A methods. Theenhancement band signal may be coded by a waveform coding method or atransform coding method.

FIG. 5 is a diagram of the structure of a preferred embodiment of aspeech signal decoder according to the present invention. An enhancementsub-band decoder 501 receives and decodes a coded enhancement bandspeech signal using a waveform coding method or a transform codingmethod, to output an enhancement band speech signal.

A base sub-band decoder 502 receives and decodes a coded base bandspeech signal according to G.723.1 or G.729A methods, to output a baseband speech signal.

A quadrature mirror filter (QMF) 503 receives the enhancement bandspeech signal and the base band speech signal from the enhancementsub-band decoder 501 and the base sub-band decoder 502. The QMF 503synthesizes the enhancement band speech signal and the base band speechsignal into one speech signal and outputs the one speech signal.

FIG. 6 is a diagram of the structure of a preferred embodiment of aspeech signal receiver according to the present invention.

An IP Network Interface 601 receives and demultiplexes a multiplexedbase band speech signal and a multiplexed enhancement band speechsignal, to extract and output a coded enhancement base speech signal anda coded base band speech signal.

A decoder 602 receives the extracted enhancement band speech signal andbase band speech signal from the IP Network Interface 601, decodes them,synthesizes them into one speech signal and outputs the single speechsignal. Here, the decoding is the same as the coding described above.The detailed structure of the decoder 602 was described in detail withreference to FIG. 5.

An acoustic echo canceller 603 receives the synthesized speech signalfrom the decoder 602 and cancels echoes from the synthesized speechsignal. The acoustic echo canceller 603 may be an acoustic echocanceller according to ITU-T G.167.

A D/A converter 604 receives the speech signal from which the echoes arecancelled, and converts the speech signal into an analog signal, whichis provided to a user via an outputting portion.

FIG. 7 is a flowchart of a preferred embodiment of a method of receivingspeech signals according to the present invention. A multiplexed speechsignal is received according to the kinds of networks, in step 701. Themultiplexed speech signal is demultiplexed and divided into anenhancement band signal and a base band signal, in step 702. Theenhancement band signal and the base band signal are separately decodedin step 703. The decoded enhancement band signal and base band signalare synthesized into one speech signal, in step 704. Echoes arecancelled from the synthesized speech signal in step 705. The speechsignal is converted from a digital signal into an analog signal in step706.

A method of decoding the speech signal is the same as the method appliedto the decoder and the speech signal receiver described with referenceto FIGS. 5 and 6.

FIG. 8 is a diagram of the structure of a preferred embodiment of anaudio communication terminal according to the present invention.Referring to FIG. 8, an A/D converter 801 receives a user's voice as ananalog speech signal through a microphone, and converts the analogspeech signal into a digital speech signal.

An acoustic echo canceller 802 cancels echoes from the digital speechsignal output from the A/D converter 801. The acoustic echo canceller802 also receives a digital speech signal from a receiving side QMF 809and cancels echoes from the digital speech signal.

A transmitting side QMF 803 receives a speech signal, from which echoesare cancelled from the user's speech signal, and divides the speechsignal into a base band signal having a bandwidth of 0-4 kHz and anenhancement band signal having a bandwidth of 4-8 kHz.

An enhancement sub-band encoder 804 receives the enhancement band signalfrom the transmitting side QMF 803, codes the enhancement band signalaccording to a waveform coding method or a transform coding method, andoutputs the coded enhancement band signal to a network connector 806.

A base sub-band encoder 805 receives the base band signal from thetransmitting side QMF 803, codes the base band signal according toG.723.1 or G.729A methods, and outputs the coded base band signal to thenetwork connector 806.

The network connector 806 receives the coded enhancement band signal andbase band signal from the enhancement sub-band encoder 804 and the basesub-band encoder 805, multiplexes the coded enhancement band signal andbase band signal, and transmits the multiplexed signal to the networksthe enhancement band signal and the base band signal, which are thespeech signals, are combined and multiplexed according to the kinds ofnetworks to which the speech signal is transmitted. In other words, ifall IP networks provided for the communication of speech signalsguarantee the QoS, the enhancement band signal and the base band signalare simultaneously packeted or only the base band signal is packeted.When a network guaranteeing the QoS and a network not guaranteeing theQoS are simultaneously provided, the relatively important base bandsignal is transmitted to the network guaranteeing the QoS, and theenhancement band signal is transmitted to the network not guaranteeingthe QoS. Here, although packet errors and jitter occur in the networknot guaranteeing the QoS, sound quality is higher than when only thebase band signal is used. If all the IP networks do not guarantee theQoS, the base band signal and the enhancement band signal may besimultaneously packeted or only the base band signal may be packeted.

The network connector 806 receives and demultiplexes a signal, from themultiplexed base band signal or the enhancement band signal, based onthe kinds of networks, and extracts and outputs a coded enhancement bandspeech signal and base band speech signal.

An enhancement sub-band decoder 807 receives the extracted enhancementband speech signal from the network connector 806 and decodes theextracted enhancement band speech signal according to a waveform codingmethod or a transform coding method.

A base sub-band decoder 808 receives the extracted enhancement bandspeech signal from the network connector 806 and decodes the extractedenhancement band speech signal according to G.723.1 or G.729A methods.

A receiving side QMF 809 receives the decoded speech signals from theenhancement sub-band decoder 807 and the base sub-band decoder 808,synthesizes the decoded speech signals into one speech signal, andoutputs the single speech signal to the acoustic echo canceller 802.

A D/A converter 810 receives a speech signal, from which echoes arecancelled, from the acoustic echo canceller 802 and converts the speechsignal into an analog speech signal. The analog speech signal may beprovided to a user via a speech signal outputting device.

Here, a digital speech signal, into which an analog speech signal isconverted, is a 16 bit linear PCM signal sampled at 16 kHz. The baseband signal is sampled at 8 kHz and has a bandwidth of 0-4 kHz. Theenhancement band signal is sampled at 8 kHz and has a bandwidth of 4-8kHz.

According to the present invention, if a user selects only a base bandsignal, the base band signal is compatible with a currently providedcoding method. Thus, a new system is unnecessary. If an enhancement bandsignal is also used, speech communication of high quality is possible.Also, speech signals are multiplexed based on the kinds of providednetworks. Thus, the speech signals can be efficiently transmitted.Moreover, echoes are cancelled from the speech signals to allow the useof a loud speaker, giving high quality live sound. Thus, bettercommunication environment can be provided.

Also, according to the present invention, it is possible to realizecomputer-readable codes in computer-readable recording media. Thecomputer-readable recording media include all kinds of recording devicesstoring computer-readable data. In other words, the computer-readablemedia include ROM, RAM, CD-ROM, magnetic tapes, floppy disks, opticaldata storing devices, and the like. Moreover, the computer-readablerecording media can be dispersed to computer systems connected to eachother via networks, stored as computer-readable codes and executed.

While this invention has been particularly shown and described withreference to preferred embodiments thereof, it will be understood bythose skilled in the art that various changes in form and details may bemade therein without departing from the spirit and scope of theinvention as defined by the appended claims. Therefore, disclosedembodiments must be considered in view of description not limitation.The scope of the present invention is shown in claims not in thedescription and all differences in the range equal to the scope of thepresent invention are construed as being included in the presentinvention.

1. A speech signal transmitter comprising: a quadrature mirror filterfor receiving a speech signal, dividing the speech signal into anenhancement band speech signal and a base band speech signal, andoutputting the enhancement band speech signal and the base band speechsignal; a base sub-band encoder for receiving and encoding the base bandspeech signal; an enhancement sub-band encoder for receiving andencoding the enhancement band speech signal; and a network connector formultiplexing the encoded enhancement band speech signal and the encodedbase band speech signal based on the kinds of networks over which speechsignals are transmitted, and transmitting the multiplexed signals to thenetworks, wherein the network connector for transmitting the encodedenhancement band speech signal and the encoded base band speech signalor the base band speech signal adaptively based on guaranteeing qualityof service.
 2. The speech signal transmitter of claim 1, wherein thebase sub-band encoder encodes the base band speech signal based onG.723.1 or G.729A.
 3. The speech signal transmitter of claim 1, whereinthe network connector simultaneously packets the enhancement band speechsignal and the base band speech signal or packets only the base bandspeech signal, if the networks are composed only of networksguaranteeing or of networks not guaranteeing quality of service, andpackets and transmits the base band speech signal to the networksguaranteeing quality of service and packets and transmits theenhancement band speech signal to the networks not guaranteeing qualityof service, if the networks are composed of networks guaranteeingquality of service and networks not guaranteeing quality of service. 4.The speech signal transmitter of claim 1, wherein the speech signal hasa sampling frequency of 16 kHz and a bandwidth of 8 kHz, the enhancementband speech signal has a sampling frequency of 8 kHz and a bandwidth of4 kHz-8 kHz, and the base band speech signal has a sampling frequency of8 kHz and a bandwidth of 0-4 kHz.
 5. The speech signal transmitter ofclaim 1, further comprising an acoustic echo canceller for receiving thespeech signal, canceling echoes from the speech signal, and outputtingthe speech signal to the quadrature mirror filter.
 6. A speech signalreceiver comprising: a network connector for receiving a speech signal,within which an enhancement band speech signal and a base band speechsignal are multiplexed based on the kinds of networks through whichspeech signals are transmitted, demultiplexing the multiplexed speechsignal, and extracting an enhancement band digital speech signal and abase band digital speech signal. an enhancement sub-band decoder forreceiving and decoding the enhancement band speech signal; a basesub-band decoder for receiving and decoding the base band speech signal;and a quadrature mirror filter for synthesizing the decoded enhancementband speech signal and the decoded base band speech signal into a singlespeech signal, wherein the network connector for receiving the encodedenhancement band speech signal and the encoded base band speech signalor the base band speech signal adaptively based on guaranteeing qualityof service.
 7. The speech signal receiver of claim 6, wherein the basesub-band decoder decodes the base band speech signal based on G.723.1 orG.729A.
 8. The speech signal receiver of claim 6, wherein theenhancement band speech signal has a sampling frequency of 8 kHz and abandwidth of 4-8 kHz, and the base band speech signal has a samplingfrequency of 8 kHz and a bandwidth of 0-4 kHz.
 9. The speech signalreceiver of claim 6, further comprising an acoustic echo canceller forcanceling echoes from the synthesized single speech signal.
 10. A methodof transmitting a speech signal comprising: receiving an analog speechsignal and converting the analog speech signal into a digital speechsignal; dividing the digital speech signal into an enhancement bandspeech signal and a base band speech signal; encoding the enhancementband speech signal and the base band speech signal, separately; andmultiplexing the encoded enhancement band speech signal and the encodedbase band speech signal, based on the kinds of networks to which thespeech signal is transmitted, and transmitting the multiplexedenhancement band speech signal and the multiplexed base band speechsignal to the networks, wherein the enhancement band speech signal andthe base band signal are simultaneously transmitted if networks areguaranteeing quality of service or only the base band speech signal ifnetworks are not guaranteeing quality of service.
 11. The method ofclaim 10, wherein the receiving the analog signal comprises cancelingechoes from the digital speech signal.
 12. The method of claim 10,wherein in the multiplexing, if the networks are composed only ofnetworks guaranteeing or of networks not guaranteeing quality ofservice, then the enhancement band speech signal and the base bandspeech signal are simultaneously packeted or only the base band speechsignal is packeted, and if the networks are composed of networksguaranteeing quality of service and networks not guaranteeing quality ofservice, the base band speech signal is packeted and transmitted to thenetworks guaranteeing quality of service and the enhancement band speechsignal is packeted and transmitted to the networks not guaranteeingquality of service.
 13. A method of receiving a speech signalcomprising: receiving a speech signal, within which an enhancement bandspeech signal and a base band speech signal are multiplexed based on thekinds of networks through which speech signals are transmitted;demultiplexing the multiplexed enhancement band speech signal and themultiplexed base band speech signal, and extracting an enhancement banddigital speech signal and a base band digital speech signal; decodingthe enhancement band digital speech signal and the base band digitalspeech signal; and synthesizing the decoded enhancement band digitalspeech signal and the decoded base band digital speech signal into asingle speech signal.
 14. The method of claim 13, wherein step thesynthesizing comprises canceling echoes from the synthesized one speechsignal.
 15. A computer-readable recording medium onto which is recordeda program for executing a method of claim 10 in a computer.